Eletromagnetic Detection of Mild Brain Injury: A Novel Imaging Approach to Post Concussive Syndrome.

James Rizkalla, David Botros, Nasser Alqahtani, Mounica Patnala, Paul Salama, Felipe Pablo Perez, Maher Rizkalla
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Abstract

Introduction: Mild traumatic brain injury (mTBI) is a common injury, with nearly 3 - 4 million cases annually in the United States alone. Neuroimaging in patients with mTBI provides little benefit, and is usually not indicated as the diagnosis is primarily clinical. It is theorized that microvascular trauma to the brain may be present in mTBI, that may not be captured by routine MRI and CT scans. Electromagnetic (EM) waves may provide a more sensitive medical imaging modality to provide objective data in the diagnosis of mTBI.

Methods: COMSOL simulation software was utilized to mimic the anatomy of the human skull including skin, cranium, cerebrospinal fluid (CSF), gray-matter tissue of the brain, and microvasculature within the neural tissue. The effects of penetrating EM waves were simulated using the finite element analysis software and results were generated to identify feasibility and efficacy. Frequency ranges from 7 GHz to 15 GHz were considered, with 0.6 and 1 W power applied.

Results: Variations between the differing frequency levels generated different energy levels within the neural tissue-particularly when comparing normal microvasculature versus hemorrhage from microvasculature. This difference within the neural tissue was subsequently identified, via simulation, serving as a potential imaging modality for future work.

Conclusion: The use of electromagnetic imaging of the brain after concussive events may play a role in future mTBI diagnosis. Utilizing the proper depth frequency and wavelength, neural tissue and microvascular trauma may be identified utilizing finite element analysis.

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轻度脑损伤的电磁检测:脑震荡后综合征的一种新成像方法。
简介:轻度创伤性脑损伤(mTBI)是一种常见的损伤,仅在美国每年就有近300 - 400万例。神经影像学在mTBI患者中提供的益处很少,而且由于诊断主要是临床诊断,通常不适用。理论上,脑微血管损伤可能存在于mTBI中,这可能不是常规MRI和CT扫描所能捕捉到的。电磁波可以为mTBI的诊断提供更灵敏的医学成像方式,为mTBI的诊断提供客观数据。方法:利用COMSOL模拟软件模拟人类颅骨的解剖结构,包括皮肤、头盖骨、脑脊液、脑灰质组织和神经组织内的微血管。利用有限元分析软件对穿透电磁波的影响进行了模拟,并得出了验证可行性和有效性的结果。频率范围从7 GHz到15 GHz,功率分别为0.6和1 W。结果:不同频率水平之间的变化在神经组织内产生不同的能量水平,特别是在比较正常微血管和微血管出血时。神经组织内的这种差异随后通过模拟被确定,作为未来工作的潜在成像模式。结论:脑震荡后的脑电磁成像可能在今后mTBI的诊断中发挥作用。利用适当的深度频率和波长,可以利用有限元分析识别神经组织和微血管损伤。
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